|Publication number||US5874208 A|
|Application number||US 08/913,682|
|Publication date||Feb 23, 1999|
|Filing date||Mar 21, 1996|
|Priority date||Mar 21, 1995|
|Also published as||DE69617655D1, DE69617655T2, EP0814820A1, EP0814820B1, WO1996029081A1|
|Publication number||08913682, 913682, PCT/1996/356, PCT/SE/1996/000356, PCT/SE/1996/00356, PCT/SE/96/000356, PCT/SE/96/00356, PCT/SE1996/000356, PCT/SE1996/00356, PCT/SE1996000356, PCT/SE199600356, PCT/SE96/000356, PCT/SE96/00356, PCT/SE96000356, PCT/SE9600356, US 5874208 A, US 5874208A, US-A-5874208, US5874208 A, US5874208A|
|Original Assignee||Omega Medicinteknik Ab|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (8), Referenced by (39), Classifications (17), Legal Events (4)|
|External Links: USPTO, USPTO Assignment, Espacenet|
1. Field of the Invention
The invention relates to blood component preparation. More specifically, the invention relates to a method and an extractor for pressing out plasma and buffy coat from a collapsible blood container, e.g. a blood bag, in which blood has been divided, by centrifugation, into a plasma layer, a buffy coat layer and a layer of red blood cells, the plasma and then the buffy coat being pressed out each through a separate outlet tube or through a common outlet tube, which is connected to the top of the blood container.
2. Description of the Related Art
In blood component preparation, blood is donated to a blood bag via a blood drawoff tube permanently connected to the bag. In addition, a number of side bags are connected to the blood bag by means of tubes. These connections are normally collected in the upper edge of the blood bag. Subsequently, the blood bag is centrifuged upright in a centrifuge cup, such that the blood forms layers, viz. an uppermost plasma layer, a subjacent buffy coat layer whose volume is relatively small, and a lowermost layer of red blood cells. At least the plasma and buffy coat fractions are then transferred to side bags by the blood bag being suspended at its upper edge in an extractor and subjected to mechanical pressure between a support surface and a pressure plate. The plasma then flows through an outlet tube over to a plasma container, while the buffy coat slowly flows upwards in the blood container. The outlet tube is normally branched into a plasma tube extending to a plasma container and a buffy coat tube extending to a buffy coat container but, alternatively, separate outlet tubes can be provided for each container. When the buffy coat has reached the top of the blood container, the plasma tube is closed and the buffy coat tube is opened. The major part of the buffy coat now flows over to the buffy coat container. However, a certain amount of buffy coat penetrates into the indentations formed by the various connections in the upper edge of the blood container, and there is a great risk that this amount remains in the blood bag after pressing-out. The remaining amount of buffy coat will mix with the red blood cell fraction and constitute a contamination therein. In manually operated extractors, one may manually press out these residues and feed them to the outlet tube, such that they can be pressed over to the buffy coat container. However, an efficient method of reaching these buffy coat residues in automatic extractors has not been available.
An object of the present invention is to provide a method and an extractor which yield a more complete discharge of the buffy coat fraction and, thus, a purer fraction of red blood cells.
The method according to the invention is characterised in that a pulsating pressure is applied to a top section or top portion or top portion of the blood container during the end phase of the pressing-out of the buffy coat. At this stage of the pressing-out operation, the buffy coat constitutes a narrow layer right at the very top at the edge of the blood container. The pulsating pressure gives the layer a pulsating motion and causes the buffy coat to be sucked out from said indentations in the edge of the blood container and flow freely towards the outlet tube for the buffy coat. This flow is additionally facilitated if the pulsating motion is not uniform along the entire width of the blood container but is designed so as to produce a pumping effect towards the outlet tube. Such a pumping effect can be achieved, for instance, by the pulsating pressure being applied on both sides of the connection of the buffy coat outlet tube to the top of the blood container.
The pulsating pressure can be produced in various ways. According to a preferred embodiment, use is made of one or more inflatable cushions abutting against the top section of the blood bag, and the pressure in said cushions is caused to pulsate at a certain selected frequency.
The inventive extractor, which comprises a stationary support surface and a movable pressing member between which the blood container is suspended and is subjected to a compressive force, is characterised by one or more inflatable cushions arranged on the support surface or pressing member or both on the same level as the top section of the blood container, and means for pulsating the pressure in said cushions.
The invention will be further described below with reference to the accompanying Figures.
FIG. 1 is a front projection of an embodiment of an extractor according to the invention.
FIG. 2 is a side projection of the extractor in FIG. 1.
FIG. 3 illustrates on a larger scale a top section of an extractor with two inflatable cushions and a device for pulsating the pressure therein.
FIG. 4 illustrates a top section of a blood container at the end of the pressing-out of the buffy coat.
FIGS. 1 and 2 illustrate an embodiment of an extractor consisting of a base with a support surface 6 and a pressing member 7, which is movable towards the support surface and which, in this case, consists of a pressure plate. The pressure plate is operated by a pressure cylinder 8. Between the support surface and the pressure plate, a blood container 1 is suspended at its upper edge from a suspension hook 9. From the top of the blood container extends an outlet tube 2, which in the illustrated embodiment branches into a plasma tube 10 extending to a plasma container (not shown) and a buffy coat tube 11 extending to a buffy coat container (not shown). Alternatively, the plasma container and the buffy coat container can each have an outlet tube 2 which is connected to the top portion of the blood container. Moreover, there are usually additional connections to the top of the blood container, for instance, a closed blood draw-off tube and a tube extending to a SAGMAN container or the like. At the top of the inside of the pressure plate, on the same level as the top section or top portion of the blood container, two inflatable cushions 12 and 13 are arranged on both sides of the connection of the outlet tube 2 to the blood container.
FIG. 3 illustrates a top section of the extractor, where the pressure plate 7 for the sake of clarity is assumed to be transparent, such that the cushions 12 and 13 and the posteriorly situated blood container 1 are clearly to be seen. The blood container is here provided with three different connections in the top, and the intermediate connection concerns a common outlet tube 2 for plasma and buffy coat. The inflatable cushions are connected via conduits 14 to a cylinder 15, which is provided with a piston 16. By a reciprocating motion of the piston, the pressure in the containers can be caused to pulsate at a selected frequency and amplitude. By exposing the cushions to a varying pressure which is higher and lower than the pressure in the blood container, the blood container part abutting against the cushions will be alternately compressed and expanded. By the pulsating volume being small relative to the volume of the blood container, its motion will be affected but to a marginal extent. The basic pressure in the blood container is determined by the pressure exerted by the pressure plate 7.
FIG. 4 illustrates the top section of the blood container during the end phase of the pressing-out of buffy coat 3 through the outlet tube 2. There are indentations 4, in which the buffy coat tends to be stuck.
The extractor functions in the following manner: A centrifuged blood container, in which the blood has been divided into an upper plasma layer, an intermediate buffy coat layer and a lower layer of red blood cells, is suspended from the suspension hook 9 and compressed between the support surface 6 and the pressure plate 7. Plasma flows out through the outlet tube 2 and further through the plasma tube 10 to a plasma container. When the buffy coat layer has reached the upper edge of the blood container, the plasma tube 10 is closed, and instead the buffy coat tube 11 is opened. Buffy coat is pressed over to a buffy coat container and, during the final stage of this pressing-out, the pulsating of the pressure in the inflatable cushions 12 and 13 is started. The pulsating pressure applied to the top section of the blood container loosens the residues of buffy coat in the indentations 4 (FIG. 4) and these can flow out through the outlet tube 2. It has been found particularly efficient, as illustrated in the Figures, to perform the pulsation on both sides of the connection of the outlet tube 2 to the blood container. A suitable frequency of the pulsation can be 10-60 pulses/min. Especially good results are obtained in conventional blood bags when pulsating at a frequency of 20-40 pulses/min.
Comparative tests with and without pulsation were carried out when pressing out plasma and buffy coat from a number of centrifuged blood bags. The result appears from the following Table.
__________________________________________________________________________Blood bag Whole blood BC RBCNo. liter Pulsation liter liter % WBC % platelets__________________________________________________________________________1 0.490 20 pulses/min 0.056 0.143 7.4 11.72 0.477 20 pulses/min 0.033 0.136 8.8 12.23 0.518 30 pulses/min 0.045 0.148 11.0 7.94 0.501 34 pulses/min 0.044 0.189 15.8 14.25 0.545 34 pulses/min 0.053 0.212 8.6 5.16 0.499 34 pulses/min 0.054 0.157 10.1 6.57 0.552 40 pulses/min 0.059 0.194 10.4 10.58 0.514 40 pulses/min 0.054 0.169 10.3 9 49 0.535 40 pulses/min 0.059 0.275 8.7 4.810 0.543 40 pulses/min 0057 0.283 8.8 5.911 0.541 40 pulses/min 0.061 0.318 10.5 5.912 0.498 No 0.046 0.155 17.6 33.813 0.489 No 0.046 0.149 26.5 30.114 0.537 No 0.043 0.184 33.6 80__________________________________________________________________________
%WBC states the proportion of the white blood cells in the blood donation that was found in the red blood cell concentrate (RBC). % platelets states the corresponding valve in respect of platelets. Thus, these values state to what extent the red blood cells were contaminated with white blood cells and platelets owing to residues of the buffy coat fraction. The Table shows that the pulsation according to the invion caused a considerably improved removal of the buffy coat fraction and, thus, a contamination of the red blood cells.
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|U.S. Classification||435/2, 222/95, 222/103, 222/214, 210/86, 210/94, 222/513, 210/109, 210/143, 222/52, 222/96, 222/23|
|Cooperative Classification||A61M1/025, A61M1/029, A61K35/14|
|Dec 31, 1997||AS||Assignment|
Owner name: OMEGA MEDICINTEKNIK AB, SWEDEN
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:UNGER, PETER;REEL/FRAME:008913/0993
Effective date: 19970814
|Sep 10, 2002||REMI||Maintenance fee reminder mailed|
|Feb 24, 2003||LAPS||Lapse for failure to pay maintenance fees|
|Apr 22, 2003||FP||Expired due to failure to pay maintenance fee|
Effective date: 20030223